DE2458677A1 - FLAT VISUAL PLATE AND PROCEDURE FOR OPERATING IT - Google Patents

Description

(Priority: December 12, 1973, Japan, No. 137 782/1973)

The invention relates to a flat direct current discharge panel, in which the main discharge is carried out by an auxiliary discharge diffusing electrons is induced, as well as a method of operating the flat viewing panel.

The prior art and the invention are illustrated with reference to the drawing

explained. Show it:

1 shows the cross section of the basic structure of a known flat display panel;

Fig. 2 is a perspective view to explain a configuration

. driving to operate the known, shown in Fig. 1; ■ th display panel;

3 shows in a cross section the basic structure of an inventive flat display panel;

Fig. 4 is a perspective view to explain a Method according to the invention for operating a display panel; '

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Pig. 5a circuit diagrams or a diagram to explain the through

¹¹¹¹ the display panel according to the invention achieved ionization couplings;

6 shows a diagram of voltage or current curves for use in the method according to the invention;

7 in a perspective illustration the structure of a Exemplary embodiment of the flat display panel according to the invention; and

Fig. 8a cross sections of a further embodiment of the

^{and 8b} display panel according to the invention.

Fig. 1 shows in cross section the basic structure of a known one flat display panel. In this, an auxiliary discharge space 2 is provided between an auxiliary anode and a cathode 3. A main discharge space 7 is located in an insulating plate 6 between the cathode 3 and an anode 9 is arranged. The spaces are filled with a known discharge gas. The one from the auxiliary discharge space 2 and the main discharge space 7 existing discharge space corresponds to a picture element for displaying a letter, a character, a number or a television picture. On one side wall of the insulating plate 6 in the main discharge space 7 phosphorus 8 is applied. For the reproduction of a television picture, for example, by means of such discharge spaces, predetermined Voltages are applied to the respective electrodes in order to discharge in the respective discharge spaces and to cause the scanning as a result of the transfer of the charge through the cathodes 3. That is, it is fed from a terminal S via a resistor R ~ Auxiliary anode 13 a DC voltage I of 250 V, from a terminal K of the Cathode 3 has a pulse voltage II with an amplitude of 100 V and a pulse voltage III with an amplitude of 120 V of a terminal A is fed to the anode 9 via a resistor R ^. By lying between the auxiliary anode 13 and the cathode 3 Voltage is generated in the auxiliary discharge space 2 plasma. Mainly the ions in the plasma diffuse into the main discharge space 7, causing the main discharge. The main

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discharge is caused by the secondary discharge mechanism, where the secondary electrons generated by the diffusion of the ions, the initial electrons are at the beginning of the main discharge. Because of this, the transition characteristics of the main discharge, for example the educational lag and the time lag, in need of improvement. Form more difficulties the energetic efficiency of the discharge, the amount of ultraviolet rays to be emitted and the efficiency of the Phosphorous excitation attributable to a small amount of radiation.

As a method for carrying out the scanning, in the case of the method shown in FIG. 1 the self-probing method (the method of Transmission of the glow discharge forming the auxiliary discharge, such as' normally applied to devices of this type). The self-scanning method is explained in more detail with reference to FIG. This only shows the arrangement of the electrodes of the known display panel. The auxiliary discharge glow or glow produced by the between the auxiliary anode 1 3 and the cathode 3 generated voltage is, by the potentials of the cathodes 3 or K-, K ,, Kp, .. '.. transferred. It is a cathode transmission device, with a cathode 3 located at the end as a reset cathode Κ- is used. The cathodes (K., K., E-),

(K ₆ , Kr-, Ko,) and (K ,, YLr, K _n ) are each common

C. O ο j D j-

switched in three phases. The auxiliary discharge glow is transferred step by step by • applying _{a reset pulse to the reset cathode terminal K / R} and pressing the respective phases onto terminals K / .., K / p and K /. To increase the scanning speed, the glow discharge must be intensified in the known method in order to increase the auxiliary discharge current. But even with a high auxiliary discharge current, the brightness does not increase. The lighting efficiency of the entire device is thus reduced.

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-JK-

The invention is based on the object of a flat display panel as well as a method to specify their operation by which the transition properties of the main discharge are improved. Further a flat display panel and a procedure for its operation should be specified, through which the energetic efficiency of the discharge or the lighting efficiency of the device can be improved.

According to the invention, the electrons are in the plasma that is in the auxiliary discharge space is generated, diffused into a main discharge space, so that the main discharge is induced by the electrons will. According to the invention, anode transfer is used, the auxiliary discharge glow being transferred by means of intermediate electrodes will.

The invention will now be explained in more detail with reference to FIGS.

Fig. 5 shows in a cross section the basic structure of a display panel according to the invention. An intermediate electrode 4 is arranged between the anode 9 and the cathode 3. The auxiliary discharge takes place between the Kahtode 3 and the intermediate electrode 4. The main discharge takes place between the anode 9 and the intermediate electrode A space in the insulating plate 6 between the anode 9 and the intermediate electrode 4 forms the main discharge space 7. A display opening 10 is formed in the anode 9 which forms part of the main discharge space forms. As voltages for the transmission of the auxiliary discharge glow are applied: from a terminal K through a resistor R ^. a DC voltage IV of -250 at the cathode 3 or -400 V; from a terminal Iv to the intermediate electrode 4 one Pulse voltage V, the level of which is between -100 V (or -25OV) and 0 V (or -250 V) is variable; and from a terminal A-. A pulse voltage to the anode 9 via a resistor R. VI, 'the level of which, for example, between 0 V (or -E ^ volts)

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and + Ep volts (or 0 volts) is variable. Diffuse in this structure mainly ions in that. in the auxiliary discharge space 2 by the voltage applied to the cathode 3 and the * intermediate electrode 4 generated plasma in the main discharge space 7. Controlled by the potential difference between the "intermediate electrode 4 and the Anode 9, can have a positive päulenaritge in the main discharge space 7 Discharge can be generated, which is an abundant source of ultraviolet rays is. Another advantage is that the display resistance R ^ is in principle superfluous because the flat display panel the main discharge not solely through the main discharge can maintain. It is also advantageous that the discharge can be kept stable because the voltage drop in Sensing resistor R 'acts as a current feedback.

Fig. 4 shows a perspective view to explain the inventive method for operating the device of FIG of the intermediate electrodes is applied. FIG. 4 shows an electrode arrangement similar to FIG. 2.

According to FIG. A , a larger number of intermediate electrodes 4 are arranged in a row. The intermediate electrode I ~ at one end of the row is used to reset. The remaining intermediate electrodes X ^, Ip, I ,, ... are for example divided into three blocks, namely into the blocks (E ^, I-, I "," ..), (Ip, I, -, Iq,. ...) and (I ,, Ig, Ig, ....). the 1 ^ 2 and I /.j example in Fig. 6 shown pulse signals I /, the terminals I / .., Ij ^ or . /, of the respective blocks supplied ^ I. the example in FIG. 6, pulse signal I / _R is shown supplied from a reset terminal I / _R, the reset-intermediate electrode I _R.

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- 4Γ-

The voltage E._ to be applied to the anode for display is synchronized with the signal voltages of the intermediate electrodes (FIG. 6). · She becomes the anode clamp. A of FIG. 3, for example, supplied by a K _o nstantstromq.uelle. As shown in FIG. 6 for AM or PV, the brightness modulation of the display takes place by means of pulse peaks (amplitude modulation) or pulse widths or numbers (current modulation) according to the input signals. The brightness modulation can also take place by means of a combination of these types of modulation.

When using the anode transfer self-sensing method in which the potentials of the intermediate electrodes can be transmitted, the indispensable in self-transmission Ion coupling are enhanced, as shown in FIGS. 5a and 5b will be explained. This has the advantage of having a low voltage fed and can be worked with high scanning speed.

Fig. 5a shows two circuits (A-1) and (A-2) for measuring the Strength of the ionization coupling in the anode transfer self-scanning method according to the invention or the known cathode transfer method. Fig. 5b shows an example of a characteristic diagram, in which the measurement results are compared under the same conditions. Voltmeter V ^ and Vg- are used for Measurement of the floating potentials fed to the Nth intermediate electrode or cathode, an ammeter M is used to measure the auxiliary discharge current.

If in the anode transfer according to the invention the discharge between the cathode 3 and the (N-1) -th intermediate_electrode 1 ^ of the intermediate electrodes 4, which is arranged opposite the common cathode 3, diffuses mainly from metastable, long-lived atoms along the auxiliary discharge space 2 and charge the adjacent N-th intermediate electrode I "to a positive potential. Compared to the case that

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between the cathode 3 and the (N-1) -th intermediate electrode 1 ^. , no discharge takes place, that from the outside for igniting the discharge between the cathode 3 and the N-th intermediate electrode IjT can be smaller by this amount. For this reason, when a certain voltage is applied to the (N-1) -th intermediate electrode I ^ _ ^ in order to induce the discharge, the discharge between the adjacent N-th intermediate electrode I ™ · and the cathode 3 becomes promoted. When the same voltage as that of the electrode 1 ^ · λ is applied to the electrode 1 ^ -, the transfer is facilitated.

According to the characteristics of FIG. 5b, the amount of charge to which the adjacent intermediate electrode is charged, or the floating potential the adjacent intermediate electrode is significantly larger in the case of the anode transfer according to the invention than in the case of known Kat ho deniib er port. With a discharge current of 100 / uA For example, the floating potential of the adjacent intermediate electrode according to the invention is about .6 times as high as in the known one Construction. As shown in FIG. 5b, the degree or the speed of the ionization coupling is strongly dependent on the size of the auxiliary discharge current between the cathode 3 and the (N-1) th Intermediate electrode I ^ ... The degree of ionization coupling is one Function of the distance between the intermediate electrodes! ".. and Ijt. If the distance is smaller, the Auxiliary discharge currents make the coupling larger.

In the case of the anode transfer, as mentioned, in contrast to the flickering of the auxiliary discharge glow as a result of the switching of the Cathode potential, the potential distribution on the common cathode surface by switching the potential of the intermediate electrodes transmitted so that the distribution of electron emission from a part of the cathode surface is controlled, which corresponds to the intermediate electrode. The electrons are therefore very easily emitted and distributed. The ionization coupling will thus intensified and the transmission facilitated. In other words, the transmission speed can be increased.

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In order to increase the scanning speed, the known display panel the auxiliary discharge current will be high. Me brightness will this is not increased, so that the brightness efficiency decreases. Since, according to the invention, the auxiliary discharge current and the main discharge current are uniform, the cutting speed can, in contrast, be and at the same time the brightness can be increased by increasing the auxiliary discharge current. Thus the efficiency not lowered.

Since the cathode 3 can be constructed from a fine wire, a high current density can be set for a certain fixed current, which is advantageous in terms of electron emission. The flat display panel according to the invention thus has many advantages over the known one.

Pig. 7 shows a practical embodiment of a display panel according to the invention. An insulating substrate 1 is provided with slots 2 which form the auxiliary discharge spaces. The cathodes 3 are arranged in the slots 2 bind. Intermediate electrodes 4, each with a number of holes 5, run perpendicular to the cathodes 3. An insulating plate 6 is arranged on the intermediate electrodes 4 and has a number of main discharge spaces 7. The main discharge spaces correspond to one or more holes 5.

In the case of a color display, the area of the main discharge space is displayed Phosphorus 8 applied. If, as shown in the cross-sections of FIGS. 8a and 8b, the main discharge space 7 is designed to be conical, this makes it easier to apply the phosphorus. Further, the directivity of the brightness, etc. are improved. 8a and 8b are cross-sections in the directions χ and y, respectively Fig. 7., ■

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The phosphor can be applied to those parts of the intermediate electrode 4 which face the main discharge spaces 7.

On the insulating plate 6 anodes 9 are applied, each z. B. consist of a metal plate or metal wire, the display openings 10 also serving as part of the main discharge spaces. the Anodes can also consist of a translucent conductor. A transparent insulating plate 11 is arranged on the anodes 9. In the case of a color display, the rear side (the side facing the anodes 9) of the translucent insulating plate 11 can be more translucent Phosphorus 12 are applied. ι '

Instead of only controlling a main discharge through an auxiliary discharge, several main discharges can also be controlled.

If a substance is applied to the cathode by means of which the coefficient of electron emission is increased, for example hexafluoride or barium oxide, so. _v , electron emission becomes particularly efficient.

The structure of the flat display panel and the - Described between electrode transfer, the basic Method of operating the panel is. The invention also relates to modifications of the feed system in which suitable Equal bias voltages applied to the anode and other electrodes or where the pulse shapes of the feed pulses are changed will. ·

Claims .

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Claims (6)

PATENT CLAIMS 1.) Flat display panel, characterized by several cathodes (3) arranged parallel to one another, by several intermediate electrodes (4) which each intersect the cathodes and are each provided with holes (5) corresponding to the interfaces with the cathodes and are also arranged parallel to one another, through anodes (9) arranged on the side of the intermediate electrodes facing away from the cathodes, which run parallel to the cathodes (3) and parallel to one another, through auxiliary discharge spaces (2) provided for the corresponding cathodes, which are common to the intermediate electrodes main discharge spaces (7) arranged in the anodes (9) corresponding to the holes (5) in the intermediate electrodes (4) and by gas hermetically enclosed in the main and auxiliary discharge spaces. 2. Display panel according to claim 1, characterized in that that a fluorescent substance (8) is applied to the main discharge spaces (7). 3. Display panel according to claim 1, characterized in that that a substance with a high electron emission coefficient is applied to the cathodes (3). 509826/0719 .24586JJ _1,. A. 4. The method for operating a display panel according to one of claims 1 to 3t, characterized in that a predetermined direct voltage is applied to the cathodes, and that a sensing voltage is applied sequentially to the intermediate electrodes zur.Übertragung the glow of the auxiliary discharge. . · 5. Flat display panel, marked by a Insulating substrate (1) with several arranged parallel to one another Slots, which each form an auxiliary discharge space (2), through cathodes (3) arranged in the slots, through themselves with the cathode intersecting intermediate electrodes (4), which are provided with holes (5) at the interfaces, through parallel to the cathodes and corresponding to the holes of the intermediate electrodes arranged anodes (9), by an insulating plate arranged between the intermediate electrodes (4) and the anodes (9) (6) with through openings at the openings (5) the points corresponding to the intermediate electrodes (4), through a transparent insulating substrate (10), which is placed on the anodes (9) is arranged, and by one in the main discharge spaces (7) formed by the through hole and in the auxiliary discharge spaces (2) contained, hermetically enclosed Gas, so that the auxiliary discharge, in the auxiliary discharge space generated electrons diffuse into the main discharge space. 509826/0719 24586? Τ " 6. A method for operating a display panel according to claim 5, characterized in that a predetermined DC voltage is applied to the cathodes, and that to the intermediate electrodes for transferring the G-liniment charge A key pulse voltage is applied to the auxiliary discharge. 509826/0719